KR102510632B1 - Radiation shielding fabric, its manufacturing method and radiation shielding articles using the same - Google Patents

Abstract

The present invention relates to a radiation shielding fabric, a manufacturing method thereof, and a radiation shielding article using the same.
The radiation shielding fabric of the present invention is made of melt-spun yarn containing barium sulfate in a PET base resin, and the fabric itself has shielding ability, so durability and reproducibility of shielding performance are secured, and high strength and elasticity are realized to medical patients. It can be applied to protective clothing, radiation shielding clothing, etc.

Description

Radiation shielding fabric, manufacturing method thereof, and radiation shielding article using the same

The present invention relates to a radiation shielding fabric, a method for manufacturing the same, and a radiation shielding article using the same, and more particularly, the radiation shielding fabric of the present invention is made of melt-spun yarn containing barium sulfate in a PET base resin, and the fabric itself is shielded. The present invention relates to a radiation shielding fabric that secures durability and reproducibility of shielding performance, and can be applied to medical patient protective clothing, radiation shielding clothing, etc. by realizing high strength and elasticity, a manufacturing method thereof, and a radiation shielding article using the same.

In general, radiation is a flow or wave of particles having energy, and is emitted from atoms, which are the most basic unit constituting matter. When protons, neutrons, and electrons constituting an atom are out of balance, they have the ability to emit radiation (radioactivity). These substances are called radioactive substances, and a kind of energy from radioactive substances is called radiation.

Radiation is divided into direct and scattered rays. Direct radiation is radiation that is directly irradiated to the test object, and scattered radiation refers to secondary radiation generated by scattering caused by direct radiation interacting with the atoms of the test object.

Exposure to direct radiation usually accompanies justification because the benefit that patients can obtain is greater than the harm caused by radiation exposure for medical diagnosis and treatment purposes.

However, exposure to scattered radiation often leads to unnecessary exposure. Specifically, the scattering rays caused by Thomson scattering, Compton scattering, etc. cause indirect exposure damage to the subject, more precisely, to the non-photographed parts of the subject that are not directly irradiated, as well as to the manpower present in the environment for image acquisition cause

In addition, it can be seen that the frequency of exposure to scattered rays is greater than that of direct rays. This is because scattered rays that cause secondary exposure do not completely penetrate the human body, resulting in accumulated exposure. Not only patients, but also medical workers such as doctors, radiographers, and nurses who are placed around patients are constantly exposed to the radiation irradiation environment due to the nature of their jobs, so there is a great risk of cumulative exposure to scattering rays.

When scattered rays, as well as direct rays, penetrate into matter, they ionize atoms or molecules to break chemical bonds. As a result, the structure of materials is changed, and in the case of living organisms, cells die or genetic information is altered, which can cause serious diseases such as cancer and mutations.

Accordingly, the 2007 ICRP New Recommendation establishes the legitimacy of medical examinations, optimization of protection from medical exposure, and dose limits for the safe use of medical radiation.

However, with the recent development of medical technology, the frequency of use of medical imaging devices such as X-ray devices and CTs has increased rapidly, and the ratio of exposure to natural radiation and artificial radiation has increased to 50:50 compared to the past 85:15. It has been reported that the risk of exposure to medical radiation is increasing.

On the other hand, efforts are being made to develop an effective radiation shielding body capable of protecting the radiation exposure environment and blocking or reducing exposure to X-rays even if they are leaked to the X-rays.

However, when the conventional radiation shielding body was developed as a heavy sheet or film made of lead harmful to the human body as a main material and made of clothing fabric, many problems were accompanied in reality.

As an example, Prior Art Document 1 discloses a radiation shielding sheet manufactured by pressure molding a mixture containing lead powder and clothing made therefrom. In order to prevent breaking or falling of toxic lead powder, a process step of pressure aging at a certain temperature and for a certain time is initiated, but by containing more than 95% by mass of lead powder for radiation shielding effect, the intrinsic weight and toxicity of lead is still maintained. Doesn't solve the problem.

Therefore, in recent years, research has been conducted to develop light and harmless radiation shielding fabrics while preventing radiation exposure.

Prior Art Document 2 discloses a radiation shielding material having eco-friendly characteristics without using a toxic organic solvent through a radiation shielding material obtained by impregnating a fiber member with a composition obtained by mixing a silicone resin with barium sulfate and a platinum catalyst and then drying it. However, the coating fiber based on liquid silicone has disadvantages in that it is difficult to form an external fabric and has poor processability and a feeling of weight, so that wearing comfort is low.

In addition, in Prior Art Document 3, a radiation shielding fiber coated after applying barium sulfate to fibers such as cotton fabric, nylon, and polyester has been proposed. In this method of weaving by coating the shielding material on the yarn, the shielding material is contained only on the outer circumferential surface of the yarn, and the coating may be detached or worn depending on external force or feeling of use, and over time, hardening occurs and the coating cracks. .

Meanwhile, various low-dose scattering rays exist around medical imaging equipment to which radiation is irradiated. Conventional medical institutions use scattering ray shielding cloths to protect patients around specific body parts, such as gonads, thyroid glands, and orbits, which are sensitive to radiation, although they are not photographed parts. However, due to the conditions of the manufacturing process, the disclosure is mainly limited to sheets of rubber or polymer materials.

Accordingly, the inventors of the present invention have made efforts to solve the conventional problems, and as a result, through a radiation shielding fabric made of melt-spun yarn containing barium sulfate in a PET base resin, the fabric itself has shielding ability, thereby improving durability and reproducibility of shielding performance. By securing, and implementing high strength and elasticity to confirm the possibility of medical or airborne radiation shielding, the present invention was completed.

Korean Registered Patent No. 1192915 (registered on October 18, 2012) Korean Patent Publication No. 20110126934 (published on November 24, 2011) Korean Patent Publication No. 19990052568 (published on February 7, 2000)

An object of the present invention is to provide a radiation shielding fabric.

Another object of the present invention is to provide a method for manufacturing a radiation shielding fabric.

Another object of the present invention is to provide a medical patient protective cloth to which the radiation shielding fabric is applied.

Another object of the present invention is to provide radiation shielding clothing to which the radiation shielding fabric is applied.

In order to achieve the above object, the present invention provides a radiation shielding fabric made of melt-spun yarn containing barium sulfate in a PET base resin.

Specifically, barium sulfate is a nanopowder having an average particle diameter of 10 to 500 nm.

In addition, the yarn satisfies the physical properties of (1) tensile strength of 3 to 5 g/d and (2) tensile elongation of 25 to 30%, and is preferably twisted yarn.

The present invention comprises the steps of preparing a master batch containing 40 to 60% by weight of barium sulfate in a PET base resin; Yarn manufacturing step of melt-spinning the master batch; Twisted yarn processing step of the yarn; And it provides a method for manufacturing a radiation shielding fabric comprising a fabric manufacturing step of manufacturing a fabric with the twisted yarn.

In the production method of the present invention, barium sulfate is pulverized to an average particle diameter of 10 to 500 nm. The PET base resin has an intrinsic viscosity (I.V) value of 0.5 to 1.

In addition, the master batch manufacturing step is performed so that the moisture content of the master batch is 5 to 20 ppm.

Furthermore, the radiation shielding fabric of the present invention can be applied as a medical patient protective cloth.

In addition, the radiation shielding fabric of the present invention can be applied as radiation shielding clothing.

The radiation shielding fabric according to an embodiment of the present invention is composed of a melt-spun yarn containing barium sulfate in a PET base resin, and can provide a radiation shielding fabric that secures radiation shielding performance and at the same time realizes high strength and elasticity. there is.

In addition, the yarn itself is manufactured to have a shielding ability rather than a method in which a conventional shielding material is coated on the outer circumferential surface, thereby providing a radiation shielding fabric with improved durability.

In addition, the radiation shielding fabric of the present invention provides a soft touch and excellent wearing comfort without difficulty in skin contact. This is suitable for medical patient protective cloths, shielding gowns, etc. that can effectively shield scattering rays emitted during medical imaging in radiation shielding medicine, for example, surgery and medical treatment. In addition, it is useful as an inner working clothes in a radiation exposure environment, a flight attendant uniform, and the like.

1 is a picture and an enlarged picture of a radiation shielding yarn of the present invention,
2 is an image of the yarn observed through an optical microscope,
3 is an image of the result of analyzing the components and cross-sections of the yarn through an energy dispersive spectrometer (EDS),
4 is a scanning electron microscope (SEM) image of (A) side and (B) cross-section of the yarn,
5 is a photograph of a radiation shielding fabric according to an embodiment of the present invention;
6 is a photograph of a radiation shielding scarf to which a radiation shielding fabric according to an embodiment of the present invention is applied.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a picture and an enlarged picture of a radiation shielding yarn of the present invention. The radiation shielding fabric of the present invention is made of melt-spun yarn containing barium sulfate in a PET base resin. Specifically, the yarn is melt-spun from a masterbatch impregnated with barium sulfate in a PET base resin, and through this, the yarn itself has shielding ability to realize a radiation shielding fabric with excellent durability and reproducibility of shielding performance. can

Figure 2 is an image of the yarn observed through an optical microscope, and the yarn was cross-sectioned with a microtome and observed under an optical microscope. As confirmed in Figure 2, barium sulfate is uniformly dispersed inside the yarn. Since the yarn itself has shielding ability, it is possible to provide a radiation shielding fabric having excellent reproducibility of durability and shielding performance.

In addition, Figure 3 is an image of the result of analyzing the components and cross section of the yarn through EDS, and the yarn contains Ba, S, and O, which are constituent elements of barium sulfate.

Barium sulfate is a white, tasteless, odorless, almost insoluble substance in water, ethanol, ether, chloroform, etc., and insoluble in acids and alkalis. In addition, it is not dissolved in gastric and intestinal juices and is not absorbed in the digestive tract, so it is used as an X-ray contrast agent when imaging the digestive tract. As such, barium sulfate is non-toxic to the human body and has a relatively excellent radiation shielding effect, making it desirable as a radiation and scattered radiation shielding medical material.

The level of radiation shielding according to the present invention is determined according to the surface area and amount of barium sulfate. The barium sulfate of the present invention is characterized in that it is contained in the form of nanopowder having an average particle diameter of 10 to 500 nm in the yarn. The barium sulfate may be a mixture of particles having two or more average size distributions.

In this way, by making barium sulfate into nanoparticles, it induces uniform dispersion and mixing in the PET base resin, and increases the probability of collision with radiation to realize excellent radiation shielding effect per unit area. In addition, a radiation shielding fabric having a smooth surface and excellent wearing comfort such as a soft touch is provided.

In addition, in the present invention, in preparing a masterbatch in which the PET base resin is impregnated with the barium sulfate, the barium sulfate may be impregnated with 40 to 60% by weight of the PET base resin.

The higher the concentration of barium sulfate in the PET base resin, the higher the probability of collision with radiation, thereby reducing the amount of transmitted radiation. However, if the barium sulfate exceeds 60% by weight, there is a concern that the dispersion may deteriorate when barium sulfate is incorporated into the PET base resin. In addition, even if it is composed of yarn, the tensile strength of the yarn is somewhat increased due to the high content of inorganic substances, which is not preferable because it may lead to a decrease in weavability of the fabric.

In order to realize a good shielding effect, it is preferable to add at least 40% by weight of barium sulfate compared to the PET base resin. If the barium sulfate is less than 40% by weight, the impregnation may be effective, but since the proportion of the PET base resin is high, the pores are large, so considering the high radiation transmittance, the shielding effect may be insufficient, which is not preferable.

Regarding the base material impregnated with barium sulfate, the embodiment of the present invention adopts PET resin. Polyethylene terephthalate (PET) has a low hygroscopicity and a high Young's modulus, and is economical in raw material cost, so it is a general purpose resin mainly consumed as a fiber by a melt spinning method.

However, the present invention is not limited thereto, and polyethylene terephthalate (PET) as well as low density polyethylene (LDPE), high density polyethylene (HDPE), polyvinylalcohol (PVA), poly olefin elastomer , POE) and polypropylene (PP).

Under the above conditions, a masterbatch impregnated with barium sulfate is melt-spun under appropriate melting conditions according to an embodiment of the present invention to secure radiation shielding performance and at the same time form a yarn suitable for weaving radiation shielding fabric by combining certain strength and elongation. let it do

4 is a scanning electron microscope (SEM) image of (A) side and (B) cross-section of the yarn. (A) In the case of the side, magnification 400 times, and (B) in the case of the cross section, the focus was taken at a magnification of 600 times. desirable.

Specifically, the yarn is characterized in that it satisfies (1) tensile strength of 3 to 5 g / d and (2) tensile elongation of 25 to 30%, and is twisted. The strength and elongation of the yarns presented in the above range are preferably used as radiation shielding fabrics, but are not limited thereto.

In addition, the yarn obtained by performing melt spinning on the masterbatch impregnated with 40 to 60% by weight of barium sulfate is characterized in that 4 to 6% by weight of barium sulfate is included. When the barium sulfate content is less than 4% by weight or greater than 6% by weight, thread breakage easily occurs during melt spinning, resulting in a decrease in yarn quality and extrusion productivity.

According to an embodiment of the present invention, the yarn implements physical properties of 75.1 d fineness, 3.14 g / d tensile strength and 29.4% tensile elongation when barium sulfate is included in 5% by weight, and is characterized in that it is twisted.

The tensile elongation value is believed to be due to the incorporation of a high content of barium sulfate for a good shielding effect, and is a factor that can affect yarn weavability. Accordingly, the present invention improves the elongation to an optimum value by performing a twisting process on the yarn. In addition, the yarn of the present invention may be made of monofilament or multifilament. According to this embodiment, the yarn is made of 36 filaments, but is not limited thereto, and the cross section of the filaments may also be made in various shapes.

The fabric produced through this is useful as a radiation shielding fabric with excellent processability and versatility by securing radiation shielding performance and at the same time having high strength and elasticity. In particular, it is suitable for medical patient protective clothing, shielding gowns, etc. that can effectively shield low-dose scattering rays emitted during medical imaging in surgical operations and medical treatment. It can also be applied to working clothes in a radiation exposure environment, flight attendant uniforms, and the like.

Hereinafter, the manufacturing method of the radiation shielding fabric of the present invention will be described. The manufacturing method of the radiation shielding fabric of the present invention includes the steps of preparing a master batch containing 40 to 60% by weight of barium sulfate in a PET base resin; Yarn manufacturing step of melt-spinning the master batch; Twisted yarn processing step of the yarn; and a fabric manufacturing step of producing fabric from the twisted yarn.

In general, radiation shielding fibers are proposed in the field by pre-spinning yarns and then coating radiation shielding materials on the outer circumferential surface of the yarns. However, the shielding fiber obtained by the above process encounters a problem in that the coating is cracked due to a hardening phenomenon over time.

Therefore, in the present invention, when producing yarn, PET base resin is impregnated with barium sulfate to prepare a master batch, and then the master batch is melt-spun, so that the radiation shielding material is stably distributed, and the yarn itself has shielding ability, resulting in excellent durability and Implement a radiation shielding fabric with reproducibility of shielding performance. According to the present invention, it is possible to solve the problem that the shielding material is contained only on the outer circumferential surface of the yarn, and the coating is easily detached or worn according to external force or feeling of use, thereby reducing the shielding ability.

In the step of preparing a master batch in which 40 to 60% by weight of barium sulfate is contained in the PET base resin of the present invention, the above numerical range is to prevent particle aggregation during melt spinning by injecting an appropriate amount of barium sulfate.

In addition, in the master batch manufacturing step of the present invention, the barium sulfate is characterized in that it is pulverized to an average particle diameter of 10 to 500 nm. The barium sulfate may be a mixture of particles having two or more average size distributions, and the range may be changed as needed.

As such, the present invention induces uniform dispersion and incorporation into the PET base resin by nanonizing barium sulfate, and increases the probability of collision with radiation to realize excellent radiation shielding effect per unit area.

In addition, in the master batch manufacturing step of the present invention, the PET base resin has an intrinsic viscosity (I.V) value of 0.5 to 1, and after impregnating the PET base resin with barium sulfate, vacuum for 35 to 40 hours characterized by drying.

This is to ensure that the moisture content of the master batch is satisfied at 5 to 20 ppm, which is preferable for producing a yarn maintaining a constant viscosity.

In the case of a moisture content exceeding 20 ppm, a non-uniform yarn is formed during melt spinning due to low viscosity, and the working environment is also deteriorated. Conversely, when the moisture content is less than 5 ppm, it is also difficult to make a uniform master batch. However, the present invention is not limited to the above numerical range.

In addition, in the master batch manufacturing step of the present invention, the master batch may be manufactured into pellets or chips by extruding using a conventional extruder, compounding machine, or twin extruder while barium sulfate is impregnated in the PET base resin. .

By preparing the master batch in advance, the miscibility can be further improved by uniformly dispersing barium sulfate in the PET base resin. In addition, when the yarn is produced, the surface is smooth, so extrusion productivity is increased, yarn breakage occurs less, and deterioration due to high-temperature kneading can be prevented, which is preferable.

In the yarn manufacturing step of melt-spinning the master batch of the present invention, after melting the master batch into an extruder, using a nozzle to cool the extruded and spun filaments in a semi-solidified state, and to collect the cooled filaments can

At this time, it is possible to manufacture a yarn by melt-spinning in mono or multi-filament through various nozzles. According to this embodiment, the yarn is made of 36 filaments, but is not limited thereto, and the cross section of the filaments may also be made in various shapes.

The yarn of the present invention prepared as described above is characterized in that barium sulfate is included in 4 to 6% by weight. It is preferable that the yarn can be stably melt-spun without cutting occurring during yarn manufacturing in the above range. In addition, the above range is a range in which barium sulfate can be optimally contained under a range that guarantees constant strength and elongation. However, the present invention is not limited thereto.

In the twisted yarn processing step of the present invention, the bundled filaments may be drawn and then wound. At this time, it is preferable to treat the yarn with 100 to 500TM, and in this embodiment, the yarn is twisted with 300TM, but it will not be limited thereto.

As described above, the present invention improves the elongation to an optimal value by performing a twisting process on the yarn before manufacturing the fabric. According to this embodiment, the yarn implements physical properties of 75.1d fineness, 3.14g/d tensile strength, and 29.4% tensile elongation when barium sulfate is included in 5% by weight. The tensile elongation value is believed to be due to the incorporation of a high content of barium sulfate for a good shielding effect, and is a factor that can affect yarn weavability. Accordingly, the present invention improves elasticity and increases strength by performing a twisting process on the yarn before manufacturing the fabric.

In addition, the fabric manufacturing step of the present invention may be to manufacture a radiation shielding fabric by weaving the obtained twisted yarn, but is not limited thereto.

5 is a photograph of a radiation shielding fabric according to an embodiment of the present invention. The radiation shielding fabric of the present invention guarantees excellent durability and reproducibility of shielding performance because the yarn itself has shielding ability, has constant strength and elongation, and realizes high strength and elasticity.

In addition, barium sulfate is included in the form of nanopowder to provide a soft touch and excellent wearing comfort without difficulty in contact with the skin.

Therefore, the radiation shielding fabric according to the present invention can be applied as a medical patient protective cloth.

Specifically, the radiation shielding fabric of the present invention is a medical patient protective cloth, shielding gown, etc. that can effectively shield low-dose radiation and scattering rays emitted during medical imaging in radiation shielding medicine, for example, surgery and treatment. Suitable.

Conventional medical radiation shielding fibers are mainly for the purpose of shielding direct lines, and are provided in the form of heavy sheets or films to realize desirable performance. In addition, patient protective cloths for the purpose of protecting non-radiated areas of patients during medical surgery are limited to rubber or polymer sheet materials in the existing technical aspects, and the price is also designated as a non-insurance fee.

According to the radiation shielding fabric of the present invention, the yarn itself has shielding ability, so the durability of the fabric is excellent and can be reused, and there is no problem in contact with the skin due to its soft touch and lightness. Therefore, when applied as a protective clothing for medical patients, it is possible to effectively protect body parts with high radiation sensitivity, such as gonads, thyroid glands, and orbital areas.

In addition, the radiation shielding fabric according to the present invention can be applied as radiation shielding clothing. For example, it is suitable for work clothes in a radiation exposure environment, natural radiation shielding clothing, and can also be used for manufacturing uniforms for flight attendants.

In particular, in the case of flight attendants who frequently fly at high altitudes due to the nature of their jobs, there is a need for radiation shielding articles using fibers that are highly sensitive to radiation, easy to process, and soft to the touch.

6 is a photograph of a radiation shielding scarf to which a radiation shielding fabric according to an embodiment of the present invention is applied. Referring to FIG. 6, a radiation shielding scarf and a radiation shielding uniform may be manufactured by applying the radiation shielding fabric of the present invention. However, the present invention is not limited thereto.

Hereinafter, the present invention will be described in more detail through examples.

These examples are intended to explain the present invention in more detail, and the scope of the present invention is not limited to these examples.

<Example> Manufacture of radiation shielding fabric

Barium sulfate was pulverized to an average particle diameter of 400 nm to obtain nanopowder, and then a PET chip having an I.V value of 0.8 was impregnated with 50% by weight of barium sulfate. Then, it was put into a twin screw compounder (Wrarner & Pfleiderer, Type ZSK 25) and melted and extruded to prepare masterbatch chips. Vacuum drying was performed for 36 hours so that the master batch satisfies the moisture content requirement of 20 ppm. Thereafter, the master batch was introduced at a speed of 25 rpm to a twin screw extruder (HAAKE Polylab RheoDrive 7, Thermo Scientific) equipped with a single spinning nozzle having a diameter of 30 μm, and the extrusion temperature was 310 ° C, the extrusion pressure was 15 bar, and the spinning pack temperature was 292 ° C. Melt spinning was performed under the condition of a pack pressure of 150 bar. The spun yarn was cooled at a cooling rate of 0.43° C./sec, then stretched and wound at a take-off roll speed of 3,230 rpm and a Godet roll speed of 3,230 rpm. Accordingly, a yarn having a barium sulfate content of 5% by weight, fineness of 75.1d, 36 multifilaments, tensile strength of 3.14g/d, and tensile elongation of 29.4% was obtained. Thereafter, a radiation shielding fabric was manufactured by weaving into a fabric through a yarn processing with 300TM.

<Comparative Example 1>

A tungsten composite yarn was prepared in the same manner as in the above example, except that the input amount of the master batch was adjusted so that the barium sulfate content in the yarn was 3% by weight. However, thread breakage occurred easily during the melt spinning process, which lowered extrusion productivity.

<Comparative Example 2>

A tungsten composite yarn was prepared in the same manner as in the above example, except that the master batch was vacuum-dried for 42 hours.

<Comparative Example 3>

A tungsten composite yarn was prepared in the same manner as in Example 1, except that 85% by weight of barium sulfate was used.

<Comparative Example 4>

A tungsten composite yarn was prepared in the same manner as in Example 1, except that barium sulfate pulverized to an average particle diameter of 400 μm was used.

<Experimental Example 1> Cross-section observation of yarn

The yarn constituting the radiation shielding fabric of the present invention, prepared in the above example, was sectioned with a microtome and observed under an optical microscope. 2 is an image of the yarn microtome observed through an optical microscope. As shown in Figure 2, it was confirmed that the yarn according to this embodiment is uniformly dispersed at a high concentration in the yarn, which is a radiation shielding material, barium sulfate. Through this, it was confirmed that the yarn itself had barium sulfate as a shielding material.

<Experimental Example 2> Component and cross-section analysis of yarn

Component and cross-section analysis was performed on the yarn prepared in the above example through energy dispersive spectroscopy (EDS).

Figure 3 is an image of the result of analyzing the components (left) and cross section (right) of the yarn through EDS, wherein the yarn contains Ba, S, and O, which are component elements of barium sulfate, which shows the cross section of the yarn It was also confirmed in the captured image.

<Experimental Example 3> Evaluation of shielding performance of fabric

The shielding performance of the radiation shielding fabric of the present invention prepared in the above example was evaluated.

The test was performed using an X-ray generator (LISTEM Co, IEX-650R, Korea). When using a narrow beam, the distance between the X-ray tube and the sample is 1500 mm, the distance between the sample and the instrument is 32 mm or more, and the instrument and the floor are 700 mm or more. , the distance between the fixed aperture and the sample was set to 200 mm, so that the appropriate distance between the X-ray tube and the shielding material suggested by the Korean Industrial Standards was kept constant.

As for the measurement method, first, the shielding rate was obtained by irradiating twice under each X-ray condition in the absence of a shielding material. Next, X-rays were irradiated to the radiation shielding fabric of the present invention under the same X-ray conditions to obtain a shielding rate.

Effective X-ray energy (keV) Shielding rate (%) Lead equivalent (mmPb) 27.7 72.7 0.018 29.9 57.9 33.6 48.7 46.7 41.2 52.3 37.5 59.7 33.1

From the results of Table 1, the radiation shielding fabric prepared in Example 1 showed a shielding rate of 72.7% when irradiated with 27.7 keV X-ray energy at 0.018 mmPb lead equivalent, and 59.7 keV X-ray energy irradiation conditions A shielding rate of 33.1% was also confirmed. Through this, it was confirmed that it can be effective for radiation shielding, especially low-dose scattering rays and natural radiation.

In addition, the radiation shielding fabric of the present invention has a lead equivalent of 0.018 mmPb, and it was confirmed that it implements excellent shielding performance while containing a very small amount of lead components harmful to the human body.

Although the present invention has been described in detail only with respect to the specific embodiments described above, it is obvious to those skilled in the art that various changes and modifications are possible within the scope of the technical idea of the present invention, and it is natural that such changes and modifications fall within the scope of the appended claims.

Claims (10)

A master batch containing 40 to 60% by weight of barium sulfate in a PET base resin is made of melt-spun yarn,
The yarn is
The barium sulfate is included in an amount of 4 to 6% by weight to prevent thread breakage occurring during the melt spinning,
The barium sulfate is a nanopowder having an average particle diameter of 10 to 500 nm, but is a mixture of particles having two or more average size distributions,
The master batch,
Prepared by impregnating the PET base resin with barium sulfate and vacuum-drying for 35 to 40 hours to satisfy a water content of 5 to 20 ppm in order to prevent the formation of non-uniform yarns during melt spinning according to viscosity,
Radiation shielding fabric, characterized in that the yarn is twisted to 100 to 500TM. delete The method of claim 1, wherein the yarn
(1) a tensile strength of 3 to 5 g/d; and
(2) A radiation shielding fabric characterized in that the tensile elongation of 25 to 30% is satisfied. delete Preparing a master batch containing 40 to 60% by weight of barium sulfate in a PET base resin;
Yarn manufacturing step of melt-spinning the master batch;
Twisted yarn processing step of the yarn; and
It consists of a fabric manufacturing step of producing fabric from the twisted yarn,
The yarn produced in the yarn manufacturing step,
In order to prevent thread breakage occurring during the melt spinning, the barium sulfate is included in an amount of 4 to 6% by weight,
The barium sulfate is a nanopowder having an average particle diameter of 10 to 500 nm, but is a mixture of particles having two or more average size distributions,
In the master batch manufacturing step,
In order to prevent the formation of non-uniform yarns during melt spinning according to viscosity, the PET base resin is impregnated with barium sulfate so that the moisture content of 5 to 20 ppm is satisfied, and then vacuum dried for 35 to 40 hours to prepare the master batch. and
The method of manufacturing a radiation shielding fabric, characterized in that the yarn in the twisted yarn processing step is treated with a twisted yarn of 100 to 500TM. delete The method of manufacturing a radiation shielding fabric according to claim 5, wherein the PET base resin has an intrinsic viscosity (I.V) value of 0.5 to 1. delete A medical patient protective cloth to which the radiation shielding fabric according to claim 1 is applied. Radiation shielding clothing to which the radiation shielding fabric according to claim 1 is applied.

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